JP6980416B2 - Rotary press-fitting device - Google Patents

Description

The present invention relates to a rotary press-fitting device that rotationally press-fits a press-fitted member.

Conventionally, a rotary press-fitting device for rotationally press-fitting a steel pipe pile as a press-fitting member into the ground has been used. In the rotary press-fitting device, a chuck frame is arranged on the leader mast so as to be movable in the vertical direction. A substantially annular chuck is rotatably arranged on the chuck frame about its central axis. The chuck frame and the chuck are provided with pile insertion holes through which steel pipe piles can be inserted in the vertical direction. The chuck can grip the steel pipe pile inserted into the pile insertion hole. When the steel pipe pile is rotationally press-fitted, the steel pipe pile is inserted into the pile insertion hole of the chuck, and the steel pipe pile is gripped by the chuck. Then, the chuck frame is moved downward to the leader mast to apply pressure input to the steel pipe pile, and the chuck is rotated to the chuck frame to apply rotational force to the steel pipe pile to apply rotational pressure to the steel pipe pile. Give input. In this way, the steel pipe pile is rotationally press-fitted into the ground (see, for example, Patent Document 1).

Japanese Unexamined Patent Publication No. 2003-138563

When the press-fitting member is rotationally press-fitted by the rotary press-fitting device, various accessory devices are attached to the press-fitting member in order to appropriately perform the rotational press-fitting. In order to operate such an accessory device, the rotary press-fitting device main body and other external supply devices and the accessory device are connected by a supply member, and supply is performed from the rotary press-fitting device main body or the like to the accessory device via the supply member. .. Here, since the accessory device is mounted on the press-fitting member, when the press-fitting member is rotationally press-fitted, the accessory device and the press-fitting member are integrally rotated, but the rotary press-fitting device The main body and the like do not rotate integrally with the press-fitted member. For this reason, if an attempt is made to perform rotary press-fitting while the supply member is connected to the accessory device, the supply member may wrap around the accessory device or the press-fitted member and be damaged. It is necessary to separate from once.

The present invention has been made in view of the above problems, and an object thereof is to supply a press-fitting member from a rotary press-fitting device to an accessory device while rotating and press-fitting the press-fitting member while the supply member is connected to the accessory device. The purpose is to provide a possible rotary press-fitting device.

According to the first embodiment of the present invention, a rotation holding portion that is rotated with respect to the apparatus main body and the apparatus main body to hold the press-fitted member, and rotates together with the held press-fitted member to rotate and press-fit the press-fitted member. The supply member is connected to the accessory device which is attached to the press-fitting member and rotates together with the press-fitting member, and the supply for operating the accessory device to the accessory device via the supply member is supplied. The rotary holding portion is a rotary press-fitting device, characterized in that it has a connecting portion to which the supply member is connected.

In the present embodiment, the supply member is connected to the accessory device and the rotation holding portion, so that the accessory device, the press-fitting member, and the rotation holding portion are rotated together when the press-fitting member is rotationally press-fitted. It has become. Therefore, even when the press-fitting member is rotationally press-fitted, the supply member does not wind around the accessory device or the press-fitting member, and the press-fitting member is rotationally press-fitted while the supply member is connected to the accessory device. It is possible to supply from the rotary press-fitting device to the accessory device.

A second embodiment of the present invention is a detection unit that detects information related to rotational press-fitting, and a control unit that controls supply to the accessory device based on the information related to the rotational press-fitting detected by the detection unit. It is a rotary press-fitting device characterized by further comprising.
In the present embodiment, the supply to the accessory device can be changed according to the situation of the rotary press-fitting, and the accessory device can be appropriately operated to perform the optimum rotary press-fitting.

In the third embodiment of the present invention, the rotation holding unit has a main body supply unit that supplies the rotation holding unit for operating the rotation holding unit, and the main body supply unit has an accessory supply unit that supplies the supply to the accessory device. It is a rotary press-fitting device that also serves as a rotary press-fitting device.
In the present embodiment, since the main body supply unit that supplies the rotation holding unit to operate the rotation holding unit also supplies the rotation holding unit to the accessory device, the configuration of the rotation holding unit can be simplified and miniaturized. There is.

In a fourth embodiment of the present invention, the rotation holding unit is provided separately from the main body supply unit that supplies the rotation holding unit to operate the rotation holding unit and the main body supply unit that supplies the rotation holding unit to the accessory device. It is a rotary press-fitting device characterized by having a portion and a portion.

In the present embodiment, since the supply for operating the rotation holding portion is performed by the main body supply unit and the supply is performed to the accessory device by the accessory supply unit separate from the main body supply unit, the accessory device is referred to as the rotation holding unit. Can be operated independently.

In the present invention, it is possible to supply the press-fitted member from the rotary press-fitting device to the accessory device while rotating and press-fitting the press-fitted member while the supply member is connected to the accessory device.

The side view which shows the rotary press-fitting system of 1st Embodiment of this invention. The top view which shows the rotary press-fitting apparatus of the 1st Embodiment of this invention. The cross-sectional view which shows the chuck of the 1st Embodiment of this invention. FIG. 3 is a vertical cross-sectional view showing the chuck of the first embodiment of the present invention cut along the line I-I of FIG. The schematic diagram which shows the hydraulic drive mechanism of 1st Embodiment of this invention. The block diagram which shows the electric power supply mechanism and the electric control mechanism of 1st Embodiment of this invention. The schematic diagram which shows the hydraulic system of the 2nd Embodiment of this invention.

The first embodiment of the present invention will be described with reference to FIGS. 1 to 6.
The rotary press-fitting system of the present embodiment will be described with reference to FIGS. 1 to 6.
The outline of the rotary press-fitting device 10 of the present embodiment will be described with reference to FIGS. 1 to 4.

As shown in FIGS. 1 to 4, the rotary press-fitting device 10 has a mast portion 20 for applying a pressure input to the steel pipe pile 98 and a chuck portion 30 for gripping the steel pipe pile 98 and applying a rotational force. And are formed from.

In the mast portion 20, the chuck frame 31 of the chuck portion 30 is connected to the leader mast 21. A main cylinder 22 is arranged on the leader mast 21, and the chuck frame 31 is movable in the vertical direction with respect to the leader mast 21 by the main cylinder 22.

In the chuck portion 30, the chuck frame 31 is provided with a chuck 32 as a rotation holding portion and a chuck rotation hydraulic motor 33. The chuck 32 has a substantially annular shape whose central axis extends in the vertical direction, and is rotatable about the central axis with respect to the chuck frame 31 by the chuck rotary hydraulic motor 33. A pile insertion hole 34 through which a steel pipe pile 98 can be inserted is extended in the vertical direction in the chuck frame 31 and the chuck 32.

The chuck 32 is provided with a chuck clamp portion 35 as a main body holding portion. The chuck clamp portion 35 is provided with a chuck claw portion 36 and a chuck opening / closing cylinder 37. Each chuck claw portion 36 corresponding to each chuck opening / closing cylinder 37 can be opened / closed in the radial direction. When the chuck claw portion 36 is closed inward in the radial direction, the steel pipe pile 98 is gripped by the chuck clamp portion 35, and the chuck claw portion 36 is opened in the radial direction by opening the chuck clamp portion 35. The steel pipe pile 98 is released from.

The outline of the downhill attachment 60 as an accessory device will be described with reference to FIGS. 1 and 5.
As shown in FIGS. 1 and 5, the downhill attachment 60 is formed of a downhill clamp portion 61 as an accessory holding portion for gripping the steel pipe pile 98 and a downhill main body portion 68 gripped by the chuck clamp portion 35. ing.

Regarding the down-down clamp portion 61, the down-down attachment 60 has a substantially circular tubular shape and can be connected to the top end portion (upper end portion) of the steel pipe pile 98 in a co-axis. That is, a downhill clamp portion 61 is disposed at the tip end portion (lower end portion) of the downhill attachment 60. The downhill clamp portion 61 can be inserted into the top end portion of the steel pipe pile 98. The down clamp portion 61 is provided with a fixed claw portion 62 and a movable claw portion 63. A plurality of gripping claws 64 that can be locked to the inner peripheral surface of the steel pipe pile 98 are disposed on the radial outer portions of the fixed claw portion 62 and the movable claw portion 63, respectively. Further, the downhill clamp portion 61 is provided with a downhill clamp portion opening / closing cylinder 67. The movable claw portion 63 can be opened and closed in the radial direction with respect to the fixed claw portion 62 by the down clamp portion opening / closing cylinder 67. The downhill clamp portion 61 is inserted into the steel pipe pile 98, the movable claw portion 63 is closed radially outward with respect to the fixed claw portion 62, and the grip claw 64 is locked to the inner peripheral surface of the steel pipe pile 98. Then, the steel pipe pile 98 is gripped by the downhill clamp portion 61. On the other hand, the movable claw portion 63 is opened radially inward with respect to the fixed claw portion 62, and the locking of the inner peripheral surface of the steel pipe pile 98 by the gripping claw 64 is released, so that the steel pipe is released from the downhill clamp portion 61. Pile 98 is released.

Regarding the downhill main body portion 68, the downhill main body portion 68 on the top end side of the downhill attachment 60 forms a circular tube having substantially the same outer diameter as the steel pipe pile 98. The downhill main body portion 68 can be inserted into the pile insertion hole 34 of the rotary press-fitting device 10 and can be gripped by the chuck clamp portion 35.

The hydraulic drive mechanism of the rotary press-fitting system will be described with reference to FIGS. 1 to 5.
As shown in FIG. 1, the rotary press-fitting system is formed with a press-fitting hydraulic circuit for applying a press-fitting input from the chuck 32 to the steel pipe pile 98.

That is, in the rotary press-fitting system, the power unit 88 that supplies hydraulic pressure is used. The power unit 88 is connected to a power unit connection port 23 arranged in the mast portion 20 of the rotary press-fitting device 10. The power unit connection port 23 is connected to the main cylinder 22 of the mast portion 20 via a main body hydraulic line 24, an electric main body hydraulic control valve 25, and a press-fit hydraulic line 26 branched from the main body hydraulic control valve 25. Hydraulic pressure is supplied from the power unit 88 to the main cylinder 22 via the main body hydraulic line 24, the main body hydraulic control valve 25, and the press-fitting hydraulic line 26. Then, by opening and closing the main body hydraulic pressure control valve 25, the hydraulic pressure supplied from the power unit 88 to the main cylinder 22 is controlled, and the chuck portion 30 is driven in the vertical direction with respect to the mast portion 20 from the chuck 32. The pressure input applied to the steel pipe pile 98 is adjusted.

Further, the rotary press-fitting system is formed with a rotary hydraulic circuit for applying a rotational force from the chuck 32 to the steel pipe pile 98.
That is, the power unit connection port 23 is connected to the chuck rotary hydraulic motor 33 of the chuck portion 30 via the main body hydraulic line 24, the main body hydraulic control valve 25, and the rotary hydraulic line 52 branched from the main body hydraulic control valve 25. Hydraulic pressure is supplied from the power unit 88 to the chuck rotary hydraulic motor 33 via the main body hydraulic line 24, the main body hydraulic control valve 25, and the rotary hydraulic line 52. Then, by opening and closing the main body hydraulic control valve 25, the hydraulic pressure supplied from the power unit 88 to the chuck rotary hydraulic motor 33 is controlled, the chuck 32 is rotationally driven with respect to the chuck frame 31, and the steel pipe pile is driven from the chuck 32. The rotational force applied to 98 is adjusted.

As shown in FIGS. 1 to 5, the rotary press-fitting system is formed with a chuck opening / closing hydraulic circuit for gripping the steel pipe pile 98 by the chuck clamp portion 35.
That is, the chuck 32 of the rotary press-fitting device 10 is provided with a hydraulic oil tank 39 for storing hydraulic oil. A chuck hydraulic system 38 as a main body supply unit and a hydraulic pressure supply unit is connected to the hydraulic oil tank 39. In the chuck hydraulic system 38, an electric chuck hydraulic pump 40 connected to the hydraulic oil tank 39 and for supplying hydraulic pressure is arranged. The chuck hydraulic pump 40 is connected to the chuck opening / closing cylinder 37 via an electric chuck opening / closing hydraulic control valve 41 and a chuck opening / closing hydraulic line 42. Hydraulic pressure is supplied from the chuck hydraulic pump 40 to the chuck opening / closing cylinder 37 via the chuck opening / closing hydraulic control valve 41 and the chuck opening / closing hydraulic line 42. Then, by opening and closing the chuck opening / closing hydraulic control valve 41, the hydraulic pressure supplied from the chuck hydraulic pump 40 to the chuck opening / closing cylinder 37 is controlled, and the chuck claw portion 36 is driven to open / close with respect to the chuck 32, and the chuck clamp is clamped. The gripping force applied to the steel pipe pile 98 is adjusted by the portion 35.

Further, in the rotary press-fitting system, a hydraulic circuit for attachment for gripping the steel pipe pile 98 is formed by the downhill clamp portion 61.
That is, in the chuck 32 of the rotary press-fitting device 10, the chuck hydraulic system 38 also serves as an accessory supply unit, and the chuck hydraulic pump 40 is hydraulic pressure as a hydraulic connection portion via the electric attachment hydraulic control valve 43 and the attachment hydraulic line 44. It is connected to the connection port 45. The attachment hydraulic control valve 43 opens the supply line of the attachment hydraulic line 44 by opening operation, closes the release line, closes the supply line by closing operation, opens the release line, and opens the supply line and release line in the stopped state. And. One end of the hydraulic pressure supply member 90 is connected to the hydraulic pressure connection port 45. A hydraulic pressure supply line 91 is formed on the hydraulic pressure supply member 90. The other end of the hydraulic pressure supply member 90 is connected to the hydraulic connection coupler 65 of the down attachment 60. The hydraulic connection coupler 65 is connected to the down-down clamp portion opening / closing cylinder 67 via the down-down clamp portion opening / closing hydraulic line 66. Hydraulic pressure is supplied from the chuck hydraulic pump 40 to the down clamp portion opening / closing cylinder 67 via the attachment hydraulic line 44 of the chuck 32, the hydraulic supply line 91 of the hydraulic supply member 90, and the down clamp portion opening / closing hydraulic line 66 of the down attachment 60. Ru. Then, by opening and closing the attachment hydraulic control valve 43, the hydraulic pressure supplied to the downhill clamp portion opening / closing cylinder 67 is controlled, and the movable claw portion 63 is driven to open / close with respect to the fixed claw portion 62 of the downhill clamp portion 61. The gripping force applied to the steel pipe pile 98 is adjusted by the down clamp portion 61.

The power supply mechanism of the rotary press-fitting system will be described with reference to FIGS. 1 and 6.
As shown in FIGS. 1 and 6, the power unit 88 used for supplying hydraulic pressure is also used for supplying electric power to the mast unit 20. The power unit 88 is connected to the power unit connection port 23 of the rotary press-fitting device 10. Electric power is supplied from the power unit 88 to the main body electric control panel 27, the main body hydraulic control valve 25, etc. arranged in the mast portion 20.

Further, in the rotary press-fitting system, a power supply device 89 for supplying electric power to the chuck 32 is used. The power supply device 89 is connected to a power supply trolley 46 as an electrical connection mechanism provided on the chuck 32. It is possible to rotate the chuck 32 with respect to the chuck frame 31 while the power supply device 89 is connected to the chuck 32. Power is supplied from the power supply device 89 to the chuck hydraulic pump 40 forming the chuck hydraulic system 38, the chuck open / close hydraulic control valve 41, the attachment hydraulic control valve 43, the chuck electric control panel 47, and the like.

The electrical control mechanism of the rotary press-fitting system will be described with reference to FIGS. 1 and 6.
As shown in FIGS. 1 and 6, in the mast portion 20 of the rotary press-fitting device 10, the press-fitting hydraulic line 26 is provided with a press-fitting sensor 28 as a detecting portion. The pressure input sensor 28 detects the pressure input value applied to the steel pipe pile 98 from the chuck 32 based on the hydraulic pressure supplied to the main cylinder 22 of the mast portion 20. Further, the rotational hydraulic line 52 is provided with a rotational force sensor 29 as a detection unit. The rotational force sensor 29 detects the rotational force value applied to the steel pipe pile 98 from the chuck 32 based on the hydraulic pressure supplied to the chuck rotational hydraulic motor 33. The pressure input sensor 28 and the rotational force sensor 29 transmit the detected pressure input value and rotational force value to the main body electric control panel 27 as a control unit, respectively.

Further, the attachment hydraulic line 44 is provided with a gripping force sensor 48 as a detection unit. The gripping force sensor 48 detects the gripping force value applied to the steel pipe pile 98 from the downhill clamp portion 61 based on the hydraulic pressure supplied to the downhill clamp portion opening / closing cylinder 67. The gripping force sensor 48 transmits the detected gripping force value to the chuck electric control panel 47. The chuck electric control panel 47 transmits the received gripping force value to the main body electric control panel 27.

The main body electric control panel 27 receives the pressure input value and the rotational force value from the pressure input sensor 28 and the rotational force sensor 29, and receives the gripping force value from the chuck electric control panel 47. Then, the main body electric control panel 27 calculates the target value of the gripping force based on the detected pressure input value and the rotational force value, and compares the target value with the detected gripping force value. The main body electric control panel 27 transmits a hydraulic pressure control signal based on the comparison result between the target value and the detected gripping force value to the chuck electric control panel 47. The chuck electric control panel 47 opens and closes the attachment hydraulic control valve 43 based on the received hydraulic pressure control signal, controls the hydraulic pressure supplied to the downhill clamp portion opening / closing cylinder 67, and the downhill clamp portion 61 controls the steel pipe pile 98. Adjust the gripping force applied to.

Next, a rotary press-fitting method of the steel pipe pile 98 using the rotary press-fitting system of the present embodiment will be described.
When the steel pipe pile 98 is rotationally press-fitted into the ground by the rotary press-fitting system, the rotary press-fitting device 10 is arranged so that the vertical direction of the rotary press-fitting device 10 substantially coincides with the vertical direction. Then, the steel pipe pile 98 is inserted into the pile insertion hole 34 of the rotary press-fitting device 10 by a crane or the like, and the steel pipe pile 98 is gripped by the chuck 32. Subsequently, in the rotary press-fitting device 10, the chuck portion 30 is moved downward with respect to the mast portion 20, pressure input is applied from the chuck 32 to the steel pipe pile 98, and the chuck 32 is rotated with respect to the chuck frame 31. Then, a rotational force is applied from the chuck 32 to the steel pipe pile 98. By applying the rotational pressure input to the steel pipe pile 98 in this way, the steel pipe pile 98 is rotationally press-fitted into the ground. When the chuck portion 30 is moved to the vicinity of the lower limit position with respect to the mast portion 20, the steel pipe pile 98 is released from the chuck 32. Then, the chuck portion 30 is moved to the vicinity of the upper limit position with respect to the mast portion 20, the steel pipe pile 98 is gripped again by the chuck 32, and a rotational pressure input is applied from the chuck 32 to the steel pipe pile 98 to apply the rotational pressure input to the steel pipe pile 98. Is rotationally press-fitted into the ground.

As described above, the steel pipe piles 98 are sequentially rotationally press-fitted, and when the grip of the steel pipe piles 98 by the chuck 32 reaches the vicinity of the top end of the steel pipe piles 98, the steel pipe piles 98 are further rotationally press-fitted into the ground. The downhill attachment 60 is connected to the steel pipe pile 98. That is, the downhill clamp portion 61 is inserted into the top end portion of the steel pipe pile 98 by a crane or the like, and the downhill attachment 60 is placed on the steel pipe pile 98. Subsequently, one end of the hydraulic pressure supply member 90 is connected to the hydraulic pressure connection coupler 65 of the down attachment 60, and the other end of the hydraulic pressure supply member 90 is connected to the hydraulic pressure connection port 45 of the chuck 32. Then, the attachment hydraulic control valve 43 of the chuck 32 is closed, and from the chuck hydraulic pump 40, the attachment hydraulic line 44 of the chuck 32, the hydraulic supply line 91 of the hydraulic supply member 90, and the down clamp portion opening / closing hydraulic line of the down attachment 60. Hydraulic pressure is supplied to the downhill clamp portion opening / closing cylinder 67 via the downhill clamp portion 66, and the top end portion of the steel pipe pile 98 is gripped by the downhill clamp portion 61.

Subsequently, the downhill attachment 60 is gripped by the chuck 32, and a rotational pressure input is applied to the downhill attachment 60 to apply a rotational pressure input to the steel pipe pile 98 connected to the downhill attachment 60, and the steel pipe pile 98 is brought to the ground. And rotate press fit. At this time, the hydraulic pressure supply member 90 for supplying hydraulic pressure to the downhill attachment 60 is connected to the hydraulic pressure connection coupler 65 of the downhill attachment 60 and the hydraulic pressure connection port 45 of the chuck 32, and the downhill attachment 60, the steel pipe pile 98 and the steel pipe pile 98. Since the chuck 32 is integrally rotated, the hydraulic pressure supply member 90 does not wind around the down attachment 60 or the steel pipe pile 98.

When the chuck portion 30 is moved to the vicinity of the lower limit position with respect to the mast portion 20, the down attachment 60 is released from the chuck 32. Then, the chuck portion 30 is moved to the vicinity of the upper limit position with respect to the mast portion 20, the downhill attachment 60 is gripped again by the chuck 32, and the steel pipe pile 98 is rotationally press-fitted into the ground. In this way, the steel pipe pile 98 is sequentially press-fitted into the ground.

As the press-fitting depth of the steel pipe pile 98 increases, the earth pressure from the ground tends to increase and the hardness of the ground also tends to increase, so that the tip resistance acting on the tip of the steel pipe pile 98 from the ground increases. .. In addition, the area of the peripheral surface of the steel pipe pile 98 in contact with the ground also increases, and the peripheral frictional resistance acting on the peripheral surface of the steel pipe pile 98 from the ground also increases. Therefore, the press-fitting resistance and the rotational resistance acting on the steel pipe pile 98 from the ground increase, and the press-fitting force and the rotational force required for rotationally press-fitting the steel pipe pile 98 also increase. As a result, the gripping force required to reliably grip the steel pipe pile 98 by the downhill clamp portion 61 also increases.

On the other hand, the main body electric control panel 27 constantly monitors the pressure input value and the rotational force value detected by the pressure input sensor 28 and the rotational force sensor 29, and the detected pressure input value and the rotational force value. The target value of the gripping force applied to the steel pipe pile 98 from the downhill clamp portion 61 is appropriately updated according to the increase. When the target value of the gripping force is increased, the main body electric control panel 27 transmits a hydraulic pressure control signal for increasing the hydraulic pressure to the chuck electric control panel 47, and the chuck electric control panel 47 transmits the received hydraulic pressure control signal to the chuck electric control panel 47. Accordingly, the attachment hydraulic control valve 43 is closed and hydraulic pressure is supplied to the downhill clamp portion opening / closing cylinder 67 to increase the gripping force applied to the steel pipe pile 98 from the downhill clamp portion 61. Here, the hydraulic connection port 45 of the chuck 32 and the hydraulic connection coupler 65 of the down attachment 60 are always connected by a hydraulic supply member 90, and hydraulic pressure is appropriately supplied from the chuck hydraulic system 38 to the down clamp portion opening / closing cylinder 67. Is possible. When the gripping force value detected by the gripping force sensor 48 reaches the target value of the gripping force, the main body electric control panel 27 stops the attachment hydraulic control valve 43, and the downhill clamp portion opening / closing cylinder from the chuck hydraulic pump 40. The hydraulic pressure supplied to 67 is stopped. In this way, the steel pipe pile 98 is gripped by the downhill clamp portion 61 with an appropriate gripping force according to the pressure input value and the rotational force value applied to the steel pipe pile 98.

Further, when the steel pipe pile 98 is rotationally press-fitted, the gripping claw 64 of the downhill clamp portion 61 shifts or slips with respect to the inner peripheral surface of the steel pipe pile 98, so that the gripping provided to the steel pipe pile 98 from the downhill clamp portion 61. The force may decrease. In this case, it is necessary to increase the gripping force applied to the steel pipe pile 98 by the downhill clamp portion 61 and to re-grip the steel pipe pile 98 by the downhill clamp portion 61.

On the other hand, the main body electric control panel 27 constantly monitors the gripping force detected by the gripping force sensor 48. Here, since the hydraulic connection coupler 65 of the down attachment 60 and the hydraulic connection port 45 of the chuck 32 are always connected by the hydraulic supply member 90, the downing is performed by the gripping force sensor 48 provided in the chuck hydraulic system 38. It is possible to constantly detect the gripping force of the clamp portion 61. When the gripping force detected by the gripping force sensor 48 becomes less than the target value, the main body electric control panel 27 transmits a hydraulic pressure control signal for increasing the hydraulic pressure to the chuck electric control panel 47, and the down clamp unit 61 sends a hydraulic pressure control signal. The gripping force applied to the steel pipe pile 98 is increased, and the steel pipe pile 98 is gripped again by the downhill clamp portion 61.
In this way, the rotary pressure input is applied to the steel pipe pile 98 using the downhill attachment 60, the steel pipe pile 98 is sequentially press-fitted into the ground, and the rotary press-fitting of the steel pipe pile 98 is completed.

The rotary press-fitting system of the present embodiment has the following effects.
In the rotary press-fitting system of the present embodiment, the hydraulic pressure supply member 90 for supplying hydraulic pressure to the downhill attachment 60 is connected to the hydraulic pressure connection coupler 65 of the downhill attachment 60 and the hydraulic pressure connection port 45 of the chuck 32. When the steel pipe pile 98 is rotationally press-fitted using the downhill attachment 60, the downhill attachment 60, the steel pipe pile 98 and the chuck 32 are integrally rotated, so that the hydraulic pressure supply member 90 is wound around the downhill attachment 60 and the steel pipe pile 98. It will not end up. Therefore, it is possible to supply hydraulic pressure from the chuck 32 to the downhill attachment 60 while rotating and press-fitting the steel pipe pile 98 using the downhill attachment 60 while the hydraulic pressure supply member 90 is connected to the chuck 32 and the downhill attachment 60. It has become.

The hydraulic connection coupler 65 for connecting the hydraulic pressure supply member 90 to the downhill attachment 60 is a rotatable coupler, and the downhill attachment 60 can be rotated with respect to the hydraulic pressure supply member 90 to supply externally such as a power unit 88. While the hydraulic pressure supply member 90 is connected to the device and the downhill attachment 60, the steel pipe pile 98 is rotationally press-fitted using the downhill attachment 60, and hydraulic pressure is supplied from the external supply device to the downhill attachment 60 via the hydraulic pressure supply member 90. It is also possible to do. However, even if a rotatable coupler is used as the hydraulic connection coupler 65, when the steel pipe pile 98 is rotationally press-fitted using the down attachment 60 while the hydraulic supply member 90 is still connected to the external supply device and the down attachment 60. There is a possibility that the hydraulic pressure supply member 90 may wind around the down attachment 60 or the steel pipe pile 98, and it is necessary to constantly monitor so that such winding does not occur. Further, in the rotatable coupler, the hydraulic pressure is sealed by the rotary seal portion. Therefore, when the hydraulic pressure to be supplied is particularly high, the down attachment 60 is rotated with respect to the hydraulic pressure supply member 90 while supplying the hydraulic pressure. Therefore, oil leakage may occur from the rotary seal portion at an early stage, which may cause environmental pollution. In the present embodiment, it is possible to omit the monitoring as described above and prevent environmental pollution.

Further, since the pressure input and the rotational force are constantly monitored by the main body electric control panel 27, and the chuck 32 and the down attachment 60 are always connected by the hydraulic pressure supply member 90, the down clamp portion opening / closing cylinder is constantly connected from the chuck hydraulic system 38. It is possible to supply hydraulic pressure to 67 as appropriate. Therefore, when the pressure input and the rotational force applied to the steel pipe pile 98 from the chuck clamp portion 35 are increased according to the press-fitting depth of the steel pipe pile 98 and the state of the ground, the down clamp portion from the chuck hydraulic system 38 By supplying hydraulic pressure to the opening / closing cylinder 67, the gripping force applied to the steel pipe pile 98 from the downhill clamp portion 61 can be increased, and the downhill clamp portion 61 can be increased according to the press-fitting depth of the steel pipe pile 98 and the condition of the ground. This makes it possible to properly grip the steel pipe pile 98.

Further, since the down-down attachment 60 and the chuck 32 are always connected by the hydraulic pressure supply member 90, the down-down clamp portion 61 applies the down-down clamp portion 61 to the steel pipe pile 98 by the gripping force sensor 48 provided in the chuck hydraulic system 38. It is possible to constantly detect the gripping force and constantly monitor it by the main body electric control panel 27. Therefore, when the steel pipe pile 98 is rotationally press-fitted using the down-down attachment 60, the gripping claw 64 of the down-down clamp portion 61 shifts or slips with respect to the inner peripheral surface of the steel pipe pile 98, and the down-down clamp portion 61 Even when the gripping force applied to the steel pipe pile 98 decreases, the gripping force applied to the steel pipe pile 98 from the downhill clamp portion 61 is increased by supplying hydraulic pressure from the chuck hydraulic system 38 to the downhill clamp portion opening / closing cylinder 67. The downhill clamp portion 61 makes it possible to re-grip the steel pipe pile 98.

In addition, the chuck hydraulic system 38 supplies hydraulic pressure to the chuck opening / closing cylinder 37 so that the steel pipe pile 98 is gripped by the chuck clamp portion 35, and hydraulic pressure is also supplied to the downhill clamp portion opening / closing cylinder 67 for downfall. The steel pipe pile 98 is gripped by the clamp portion 61. That is, the chuck hydraulic system 38 for gripping the steel pipe pile 98 by the chuck 32 is also used for gripping the steel pipe pile 98 by the down clamp portion 61, simplifying the configuration of the chuck 32 and reducing the size of the chuck 32. It is possible.

A second embodiment of the present invention will be described with reference to FIG. 7.
As shown in FIG. 7, in the rotary press-fitting system of the present embodiment, the chuck 32 is provided with a chuck hydraulic system 38 and an attachment hydraulic system 49. Similar to the first embodiment, the chuck hydraulic system 38 is connected to the hydraulic oil tank 39 and is formed of the chuck hydraulic pump 40 and the chuck open / close hydraulic control valve 41. The chuck open / close cylinder via the chuck open / close hydraulic line 42. It is connected to 37. Further, the attachment hydraulic system 49 is connected to the hydraulic oil tank 39, is formed of the electric attachment hydraulic pump 51 and the attachment hydraulic control valve 43, and is connected to the hydraulic connection port 45 via the attachment hydraulic line 44. ..

As described above, in the rotary press-fitting system of the present embodiment, the hydraulic circuit for attachment for gripping the steel pipe pile 98 by the downhill clamp portion 61 and the hydraulic circuit for opening and closing the chuck for gripping the steel pipe pile 98 by the chuck clamp portion 35. It is formed separately and independently. Therefore, the downhill clamp portion 61 can be operated independently of the chuck clamp portion 35.

In the present embodiment, the hydraulic oil tank 39 common to the chuck hydraulic system 38 and the attachment hydraulic system 49 is used, but even if separate hydraulic oil tanks are used for the chuck hydraulic system 38 and the attachment hydraulic system 49. good.

In each of the above embodiments, a steel pipe pile made of steel and a tubular steel pipe pile is used as the press-fitting member to be rotationally press-fitted into the ground, but various other members can be used.

Further, as the accessory device attached to the press-fitting member and rotated together with the press-fitting member, a downhill attachment is used, but various other accessory devices can be used. For example, it is possible to use an auger attachment for excavating the ground, and when a clamp mechanism for gripping a steel pipe pile and an excavation mechanism for excavating the ground are used in the auger attachment, a hydraulic pressure supply member is used from the chuck hydraulic system. The hydraulic pressure may be supplied to the clamp mechanism and the excavation mechanism of the auger attachment to operate the clamp mechanism and the excavation mechanism by the hydraulic pressure.

Further, although the hydraulic pressure is supplied from the rotary press-fitting device to the accessory device, various supply targets can be supplied to the accessory device. For example, when an auger attachment is used as an accessory device and an air lubrication system that reduces friction during excavation of the ground is used in the auger attachment, an air supply member is connected to the air connection port of the chuck to connect the air compressor of the chuck. Therefore, air may be supplied to the air lubrication system of the auger attachment via the air supply member. When an electric drive mechanism such as an electro-hydraulic control valve is used as an accessory device, a power supply member is connected to the electric connection port of the chuck, and the power supplied from the power supply device to the chuck via the power supply trolley is supplied. It may be supplied to the electric drive mechanism of the accessory device via the power supply member. In this case, the electric control panel of the chuck may be connected to the electric drive mechanism of the accessory device via the electric supply member, and the electric drive mechanism of the accessory device may be controlled by the electric control panel of the chuck.

10 Rotary press-fitting device 27 Main body electric control panel 28 Pressure input sensor 29 Rotary force sensor 32 Chuck 35 Chuck clamp part 38 Chuck hydraulic system 39 Hydraulic oil tank 40 Chuck hydraulic pump 41 Chuck open / close hydraulic control valve 43 Attachment hydraulic control valve 45 Hydraulic connection port 46 Power supply trolley 47 Chuck electric control panel 48 Grip force sensor 49 Attachment hydraulic system 51 Attachment hydraulic pump 60 Down attachment 61 Down down clamp 89 Power supply device 90 Hydraulic supply member 98 Steel pipe pile

Claims (6)

With the device body
A rotary holding portion that is rotated with respect to the main body of the apparatus , holds the press-fitted member from the outside of the press-fitted member, rotates together with the held press-fitted member, and rotationally press-fits the press-fitted member into the ground.
Equipped with
One end of a supply member that supplies hydraulic pressure, electric power, or a lubricant is connected to an accessory device that is attached to the press-fitted member and rotates together with the press-fitted member, and the accessory device is connected to the accessory device via the supply member. A hydraulic pressure, power or lubricant is supplied to operate,
The rotation holding portion has a connecting portion to which the other end of the supply member is connected.
A rotary press-fitting device characterized by this. And press-fitting force or rotational force detecting unit detects the press-fitting force or rotational force in a rotational press fitting,
The force-insertion force or gripping the rotating force by controlling the hydraulic pressure supply to the accessory device based on the pressure input or rotational force definitive the rotary press fitted detected by the detecting unit is applied to the pressed insertion member from said accessory device The control unit that adjusts the force and
The rotary press-fitting device according to claim 1, further comprising. The rotary holding unit includes a main body supply unit for performing hydraulic or electric power supply for operating the rotation holding portion, the body supply unit accessory supply unit for supplying hydraulic or electric power to the accessory device Also serves as
The rotary press-fitting device according to claim 1. The rotation holding unit is an accessory supply unit that is separate from the main body supply unit that supplies hydraulic pressure or electric power for operating the rotation holding unit and the main body supply unit that supplies hydraulic pressure or electric power to the accessory device. And have,
The rotary press-fitting device according to claim 1. The rotation holding unit has a supply unit for supplying to the accessory device, and has a supply unit.
The supply unit, the supply member, and the connection unit are, respectively, a hydraulic pressure supply unit, a hydraulic pressure supply member, and a hydraulic pressure connection unit, and the hydraulic pressure supply unit is driven by electric power.
The rotation holding unit has an electrical connection mechanism that enables rotation of the rotation holding unit with respect to the device main body in a state where a power supply device for supplying electric power is connected to the hydraulic pressure supply unit and the power supply device is connected.
The rotary press-fitting device according to claim 1. The hydraulic pressure supply unit is a hydraulic system including an electric hydraulic pump, an electric hydraulic control valve, and an electric control panel.
The electrical connection mechanism is a power supply trolley.
The rotary press-fitting device according to claim 5.

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